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openmpi/ompi/runtime/ompi_mpi_init.c

948 строки
35 KiB
C
Исходник Обычный вид История

/*
* Copyright (c) 2004-2007 The Trustees of Indiana University and Indiana
* University Research and Technology
* Corporation. All rights reserved.
* Copyright (c) 2004-2008 The University of Tennessee and The University
* of Tennessee Research Foundation. All rights
* reserved.
* Copyright (c) 2004-2005 High Performance Computing Center Stuttgart,
* University of Stuttgart. All rights reserved.
* Copyright (c) 2004-2005 The Regents of the University of California.
* All rights reserved.
* Copyright (c) 2006-2009 Cisco Systems, Inc. All rights reserved.
* Copyright (c) 2006-2007 Los Alamos National Security, LLC. All rights
* reserved.
* Copyright (c) 2006-2009 University of Houston. All rights reserved.
* Copyright (c) 2008-2009 Sun Microsystems, Inc. All rights reserved.
*
* $COPYRIGHT$
*
* Additional copyrights may follow
*
* $HEADER$
*/
#include "ompi_config.h"
#ifdef HAVE_SYS_TIME_H
#include <sys/time.h>
#endif /* HAVE_SYS_TIME_H */
#ifdef HAVE_PTHREAD_H
#include <pthread.h>
#endif
#ifdef HAVE_UNISTD_H
#include <unistd.h>
#endif
#include "mpi.h"
#include "opal/class/opal_list.h"
#include "opal/mca/base/base.h"
#include "opal/mca/paffinity/base/base.h"
#include "opal/mca/maffinity/base/base.h"
#include "opal/runtime/opal_progress.h"
#include "opal/threads/threads.h"
#include "opal/util/output.h"
#include "opal/util/error.h"
#include "opal/util/stacktrace.h"
#include "opal/util/show_help.h"
#include "opal/runtime/opal.h"
#include "opal/event/event.h"
#include "orte/util/proc_info.h"
#include "orte/runtime/runtime.h"
#include "orte/mca/grpcomm/grpcomm.h"
#include "orte/runtime/orte_globals.h"
#include "orte/util/show_help.h"
#include "orte/mca/ess/ess.h"
#include "orte/mca/errmgr/errmgr.h"
#include "orte/util/name_fns.h"
#include "orte/mca/notifier/notifier.h"
#include "ompi/constants.h"
#include "ompi/mpi/f77/constants.h"
#include "ompi/runtime/mpiruntime.h"
#include "ompi/runtime/params.h"
#include "ompi/runtime/ompi_module_exchange.h"
#include "ompi/communicator/communicator.h"
#include "ompi/info/info.h"
#include "ompi/errhandler/errcode.h"
#include "ompi/request/request.h"
#include "ompi/op/op.h"
Two major things in this commit: * New "op" MPI layer framework * Addition of the MPI_REDUCE_LOCAL proposed function (for MPI-2.2) = Op framework = Add new "op" framework in the ompi layer. This framework replaces the hard-coded MPI_Op back-end functions for (MPI_Op, MPI_Datatype) tuples for pre-defined MPI_Ops, allowing components and modules to provide the back-end functions. The intent is that components can be written to take advantage of hardware acceleration (GPU, FPGA, specialized CPU instructions, etc.). Similar to other frameworks, components are intended to be able to discover at run-time if they can be used, and if so, elect themselves to be selected (or disqualify themselves from selection if they cannot run). If specialized hardware is not available, there is a default set of functions that will automatically be used. This framework is ''not'' used for user-defined MPI_Ops. The new op framework is similar to the existing coll framework, in that the final set of function pointers that are used on any given intrinsic MPI_Op can be a mixed bag of function pointers, potentially coming from multiple different op modules. This allows for hardware that only supports some of the operations, not all of them (e.g., a GPU that only supports single-precision operations). All the hard-coded back-end MPI_Op functions for (MPI_Op, MPI_Datatype) tuples still exist, but unlike coll, they're in the framework base (vs. being in a separate "basic" component) and are automatically used if no component is found at runtime that provides a module with the necessary function pointers. There is an "example" op component that will hopefully be useful to those writing meaningful op components. It is currently .ompi_ignore'd so that it doesn't impinge on other developers (it's somewhat chatty in terms of opal_output() so that you can tell when its functions have been invoked). See the README file in the example op component directory. Developers of new op components are encouraged to look at the following wiki pages: https://svn.open-mpi.org/trac/ompi/wiki/devel/Autogen https://svn.open-mpi.org/trac/ompi/wiki/devel/CreateComponent https://svn.open-mpi.org/trac/ompi/wiki/devel/CreateFramework = MPI_REDUCE_LOCAL = Part of the MPI-2.2 proposal listed here: https://svn.mpi-forum.org/trac/mpi-forum-web/ticket/24 is to add a new function named MPI_REDUCE_LOCAL. It is very easy to implement, so I added it (also because it makes testing the op framework pretty easy -- you can do it in serial rather than via parallel reductions). There's even a man page! This commit was SVN r20280.
2009-01-15 02:44:31 +03:00
#include "ompi/mca/op/op.h"
#include "ompi/mca/op/base/base.h"
#include "ompi/file/file.h"
#include "ompi/attribute/attribute.h"
#include "ompi/mca/allocator/base/base.h"
#include "ompi/mca/rcache/base/base.h"
#include "ompi/mca/rcache/rcache.h"
#include "ompi/mca/mpool/base/base.h"
#include "ompi/mca/pml/pml.h"
#include "ompi/mca/pml/base/base.h"
#include "ompi/mca/osc/base/base.h"
#include "ompi/mca/coll/base/base.h"
#include "ompi/mca/io/io.h"
#include "ompi/mca/io/base/base.h"
#include "ompi/debuggers/debuggers.h"
#include "ompi/proc/proc.h"
#include "ompi/mca/pml/base/pml_base_bsend.h"
#include "ompi/mca/dpm/base/base.h"
#include "ompi/mca/pubsub/base/base.h"
#if OPAL_ENABLE_FT == 1
#include "ompi/mca/crcp/crcp.h"
#include "ompi/mca/crcp/base/base.h"
#endif
#include "ompi/runtime/ompi_cr.h"
#include "orte/runtime/orte_globals.h"
/* This is required for the boundaries of the hash tables used to store
* the F90 types returned by the MPI_Type_create_f90_XXX functions.
*/
#include <float.h>
#if OPAL_CC_USE_PRAGMA_IDENT
#pragma ident OMPI_IDENT_STRING
#elif OPAL_CC_USE_IDENT
#ident OMPI_IDENT_STRING
#endif
const char ompi_version_string[] = OMPI_IDENT_STRING;
/*
* Global variables and symbols for the MPI layer
*/
bool ompi_mpi_initialized = false;
bool ompi_mpi_finalized = false;
bool ompi_mpi_thread_multiple = false;
int ompi_mpi_thread_requested = MPI_THREAD_SINGLE;
int ompi_mpi_thread_provided = MPI_THREAD_SINGLE;
opal_thread_t *ompi_mpi_main_thread = NULL;
bool ompi_mpi_maffinity_setup = false;
bool ompi_warn_on_fork;
#if OPAL_HAVE_POSIX_THREADS
static bool fork_warning_issued = false;
static bool atfork_called = false;
static void warn_fork_cb(void)
{
if (ompi_mpi_initialized && !ompi_mpi_finalized && !fork_warning_issued) {
orte_show_help("help-mpi-runtime.txt", "mpi_init:warn-fork", true,
orte_process_info.nodename, getpid(),
ompi_mpi_comm_world.comm.c_my_rank);
fork_warning_issued = true;
}
}
#endif
void ompi_warn_fork(void)
{
#if OPAL_HAVE_POSIX_THREADS
if (ompi_warn_on_fork && !atfork_called) {
pthread_atfork(warn_fork_cb, NULL, NULL);
atfork_called = true;
}
#endif
}
/*
* These variables are here, rather than under ompi/mpi/c/foo.c
* because it is not sufficient to have a .c file that only contains
* variables -- you must have a function that is invoked from
* elsewhere in the code to guarantee that all linkers will pull in
* the .o file from the library. Hence, although these are MPI
* constants, we might as well just define them here (i.e., in a file
* that already has a function that is guaranteed to be linked in,
* rather than make a new .c file with the constants and a
* corresponding dummy function that is invoked from this function).
*
Clean up the Fortran MPI sentinel values per problem reported on the users mailing list: http://www.open-mpi.org/community/lists/users/2006/07/1680.php Warning: this log message is not for the weak. Read at your own risk. The problem was that we had several variables in Fortran common blocks of various types, but their C counterparts were all of a type equivalent to a fortran double complex. This didn't seem to matter for the compilers that we tested, but we never tested static builds (which is where this problem seems to occur, at least with the Intel compiler: the linker compilains that the variable in the common block in the user's .o file was of one size/alignment but the one in the C library was a different size/alignment). So this patch fixes the sizes/types of the Fortran common block variables and their corresponding C instantiations to be of the same sizes/types. But wait, there's more. We recently introduced a fix for the OSX linker where some C versions of the fortran common block variables (e.g., _ompi_fortran_status_ignore) were not being found when linking ompi_info (!). Further research shows that the code path for ompi_info to require ompi_fortran_status_ignore is, unfortunately, necessary (a quirk of how various components pull in different portions of the code base -- nothing in ompi_info itself requires fortran or MPI knowledge, of course). Hence, the real problem was that there was no code path from ompi_info to the portion of the code base where the C globals corresponding to the Fortran common block variables were instantiated. This is because the OSX linker does not automatically pull in .o files that only contain unintialized global variables; the OSX linker typically only pulls in a .o file from a library if it either has a function that is used or have a global variable that is initialized (that's the short version; lots of details and corner cases omitted). Hence, we changed the global C variables corresponding to the fortran common blocks to be initialized, thereby causing the OSX linker to pull them in automatically -- problem solved. At the same time, we moved the constants to another .c file with a function, just for good measure. However, this didn't really solve the problem: 1. The function in the file with the C versions of the fortran common block variables (ompi/mpi/f77/test_constants_f.c) did not have a code path that was reachable from ompi_info, so the only reason that the constants were found (on OSX) was because they were initialized in the global scope (i.e., causing the OSX compiler to pull in that .o file). 2. Initializing these variable in the global scope causes problems for some linkers where -- once all the size/type problems mentioned above were fixed -- the alignments of fortran common blocks and C global variables do not match (even though the types of the Fortran and C variables match -- wow!). Hence, initializing the C variables would not necessarily match the alignment of what Fortran expected, and the linker would issue a warning (i.e., the alignment warnings referenced in the original post). The solution is two-fold: 1. Move the Fortran variables from test_constants_f.c to ompi/mpi/runtime/ompi_mpi_init.c where there are other global constants that *are* initialized (that had nothing to do with fortran, so the alignment issues described above are not a factor), and therefore all linkers (including the OSX linker) will pull in this .o file and find all the symbols that it needs. 2. Do not initialize the C variables corresponding to the Fortran common blocks in the global scope. Indeed, never initialize them at all (because we never need their *values* - we only check for their *locations*). Since nothing is ever written to these variables (particularly in the global scope), the linker does not see any alignment differences during initialization, but does make both the C and Fortran variables have the same addresses (this method has been working in LAM/MPI for over a decade). There were some comments here in the OMPI code base and in the LAM code base that stated/implied that C variables corresponding to Fortran common blocks had to have the same alignment as the Fortran common blocks (i.e., 16). There were attempts in both code bases to ensure that this was true. However, the attempts were wrong (in both code bases), and I have now read enough Fortran compiler documentation to convince myself that matching alignments is not required (indeed, it's beyond our control). As long as C variables corresponding to Fortran common blocks are not initialized in the global scope, the linker will "figure it out" and adjust the alignment to whatever is required (i.e., the greater of the alignments). Specifically (to counter comments that no longer exist in the OMPI code base but still exist in the LAM code base): - there is no need to make attempts to specially align C variables corresponding to Fortran common blocks - the types and sizes of C variables corresponding to Fortran common blocks should match, but do not need to be on any particular alignment Finally, as a side effect of this effort, I found a bunch of inconsistencies with the intent of status/array_of_statuses parameters. For all the functions that I modified they should be "out" (not inout). This commit was SVN r11057.
2006-07-31 19:07:09 +04:00
* Additionally, there can be/are strange linking paths such that
* ompi_info needs symbols such as ompi_fortran_status_ignore,
Clean up the Fortran MPI sentinel values per problem reported on the users mailing list: http://www.open-mpi.org/community/lists/users/2006/07/1680.php Warning: this log message is not for the weak. Read at your own risk. The problem was that we had several variables in Fortran common blocks of various types, but their C counterparts were all of a type equivalent to a fortran double complex. This didn't seem to matter for the compilers that we tested, but we never tested static builds (which is where this problem seems to occur, at least with the Intel compiler: the linker compilains that the variable in the common block in the user's .o file was of one size/alignment but the one in the C library was a different size/alignment). So this patch fixes the sizes/types of the Fortran common block variables and their corresponding C instantiations to be of the same sizes/types. But wait, there's more. We recently introduced a fix for the OSX linker where some C versions of the fortran common block variables (e.g., _ompi_fortran_status_ignore) were not being found when linking ompi_info (!). Further research shows that the code path for ompi_info to require ompi_fortran_status_ignore is, unfortunately, necessary (a quirk of how various components pull in different portions of the code base -- nothing in ompi_info itself requires fortran or MPI knowledge, of course). Hence, the real problem was that there was no code path from ompi_info to the portion of the code base where the C globals corresponding to the Fortran common block variables were instantiated. This is because the OSX linker does not automatically pull in .o files that only contain unintialized global variables; the OSX linker typically only pulls in a .o file from a library if it either has a function that is used or have a global variable that is initialized (that's the short version; lots of details and corner cases omitted). Hence, we changed the global C variables corresponding to the fortran common blocks to be initialized, thereby causing the OSX linker to pull them in automatically -- problem solved. At the same time, we moved the constants to another .c file with a function, just for good measure. However, this didn't really solve the problem: 1. The function in the file with the C versions of the fortran common block variables (ompi/mpi/f77/test_constants_f.c) did not have a code path that was reachable from ompi_info, so the only reason that the constants were found (on OSX) was because they were initialized in the global scope (i.e., causing the OSX compiler to pull in that .o file). 2. Initializing these variable in the global scope causes problems for some linkers where -- once all the size/type problems mentioned above were fixed -- the alignments of fortran common blocks and C global variables do not match (even though the types of the Fortran and C variables match -- wow!). Hence, initializing the C variables would not necessarily match the alignment of what Fortran expected, and the linker would issue a warning (i.e., the alignment warnings referenced in the original post). The solution is two-fold: 1. Move the Fortran variables from test_constants_f.c to ompi/mpi/runtime/ompi_mpi_init.c where there are other global constants that *are* initialized (that had nothing to do with fortran, so the alignment issues described above are not a factor), and therefore all linkers (including the OSX linker) will pull in this .o file and find all the symbols that it needs. 2. Do not initialize the C variables corresponding to the Fortran common blocks in the global scope. Indeed, never initialize them at all (because we never need their *values* - we only check for their *locations*). Since nothing is ever written to these variables (particularly in the global scope), the linker does not see any alignment differences during initialization, but does make both the C and Fortran variables have the same addresses (this method has been working in LAM/MPI for over a decade). There were some comments here in the OMPI code base and in the LAM code base that stated/implied that C variables corresponding to Fortran common blocks had to have the same alignment as the Fortran common blocks (i.e., 16). There were attempts in both code bases to ensure that this was true. However, the attempts were wrong (in both code bases), and I have now read enough Fortran compiler documentation to convince myself that matching alignments is not required (indeed, it's beyond our control). As long as C variables corresponding to Fortran common blocks are not initialized in the global scope, the linker will "figure it out" and adjust the alignment to whatever is required (i.e., the greater of the alignments). Specifically (to counter comments that no longer exist in the OMPI code base but still exist in the LAM code base): - there is no need to make attempts to specially align C variables corresponding to Fortran common blocks - the types and sizes of C variables corresponding to Fortran common blocks should match, but do not need to be on any particular alignment Finally, as a side effect of this effort, I found a bunch of inconsistencies with the intent of status/array_of_statuses parameters. For all the functions that I modified they should be "out" (not inout). This commit was SVN r11057.
2006-07-31 19:07:09 +04:00
* which, if they weren't here with a collection of other global
* symbols that are initialized (which seems to force this .o file to
* be pulled into the resolution process, because ompi_info certainly
* does not call ompi_mpi_init()), would not be able to be found by
* the OSX linker.
*
* NOTE: See the big comment in ompi/mpi/f77/constants.h about why we
* have four symbols for each of the common blocks (e.g., the Fortran
* equivalent(s) of MPI_STATUS_IGNORE). Here, we can only have *one*
* value (not four). So the only thing we can do is make it equal to
* the fortran compiler convention that was selected at configure
* time. Note that this is also true for the value of .TRUE. from the
* Fortran compiler, so even though Open MPI supports all four Fortran
* symbol conventions, it can only support one convention for the two
* C constants (MPI_FORTRAN_STATUS[ES]_IGNORE) and only support one
* compiler for the value of .TRUE. Ugh!!
*
* Note that the casts here are ok -- we're *only* comparing pointer
* values (i.e., they'll never be de-referenced). The global symbols
* are actually of type (ompi_fortran_common_t) (for alignment
* issues), but MPI says that MPI_F_STATUS[ES]_IGNORE must be of type
* (MPI_Fint*). Hence, we have to cast to make compilers not
* complain.
*/
#if OMPI_WANT_F77_BINDINGS
# if OMPI_F77_CAPS
MPI_Fint *MPI_F_STATUS_IGNORE = (MPI_Fint*) &MPI_FORTRAN_STATUS_IGNORE;
MPI_Fint *MPI_F_STATUSES_IGNORE = (MPI_Fint*) &MPI_FORTRAN_STATUSES_IGNORE;
# elif OMPI_F77_PLAIN
MPI_Fint *MPI_F_STATUS_IGNORE = (MPI_Fint*) &mpi_fortran_status_ignore;
MPI_Fint *MPI_F_STATUSES_IGNORE = (MPI_Fint*) &mpi_fortran_statuses_ignore;
# elif OMPI_F77_SINGLE_UNDERSCORE
MPI_Fint *MPI_F_STATUS_IGNORE = (MPI_Fint*) &mpi_fortran_status_ignore_;
MPI_Fint *MPI_F_STATUSES_IGNORE = (MPI_Fint*) &mpi_fortran_statuses_ignore_;
# elif OMPI_F77_DOUBLE_UNDERSCORE
MPI_Fint *MPI_F_STATUS_IGNORE = (MPI_Fint*) &mpi_fortran_status_ignore__;
MPI_Fint *MPI_F_STATUSES_IGNORE = (MPI_Fint*) &mpi_fortran_statuses_ignore__;
# else
# error Unrecognized Fortran 77 name mangling scheme
# endif
#else
MPI_Fint *MPI_F_STATUS_IGNORE = NULL;
MPI_Fint *MPI_F_STATUSES_IGNORE = NULL;
#endif /* OMPI_WANT_F77_BINDINGS */
Clean up the Fortran MPI sentinel values per problem reported on the users mailing list: http://www.open-mpi.org/community/lists/users/2006/07/1680.php Warning: this log message is not for the weak. Read at your own risk. The problem was that we had several variables in Fortran common blocks of various types, but their C counterparts were all of a type equivalent to a fortran double complex. This didn't seem to matter for the compilers that we tested, but we never tested static builds (which is where this problem seems to occur, at least with the Intel compiler: the linker compilains that the variable in the common block in the user's .o file was of one size/alignment but the one in the C library was a different size/alignment). So this patch fixes the sizes/types of the Fortran common block variables and their corresponding C instantiations to be of the same sizes/types. But wait, there's more. We recently introduced a fix for the OSX linker where some C versions of the fortran common block variables (e.g., _ompi_fortran_status_ignore) were not being found when linking ompi_info (!). Further research shows that the code path for ompi_info to require ompi_fortran_status_ignore is, unfortunately, necessary (a quirk of how various components pull in different portions of the code base -- nothing in ompi_info itself requires fortran or MPI knowledge, of course). Hence, the real problem was that there was no code path from ompi_info to the portion of the code base where the C globals corresponding to the Fortran common block variables were instantiated. This is because the OSX linker does not automatically pull in .o files that only contain unintialized global variables; the OSX linker typically only pulls in a .o file from a library if it either has a function that is used or have a global variable that is initialized (that's the short version; lots of details and corner cases omitted). Hence, we changed the global C variables corresponding to the fortran common blocks to be initialized, thereby causing the OSX linker to pull them in automatically -- problem solved. At the same time, we moved the constants to another .c file with a function, just for good measure. However, this didn't really solve the problem: 1. The function in the file with the C versions of the fortran common block variables (ompi/mpi/f77/test_constants_f.c) did not have a code path that was reachable from ompi_info, so the only reason that the constants were found (on OSX) was because they were initialized in the global scope (i.e., causing the OSX compiler to pull in that .o file). 2. Initializing these variable in the global scope causes problems for some linkers where -- once all the size/type problems mentioned above were fixed -- the alignments of fortran common blocks and C global variables do not match (even though the types of the Fortran and C variables match -- wow!). Hence, initializing the C variables would not necessarily match the alignment of what Fortran expected, and the linker would issue a warning (i.e., the alignment warnings referenced in the original post). The solution is two-fold: 1. Move the Fortran variables from test_constants_f.c to ompi/mpi/runtime/ompi_mpi_init.c where there are other global constants that *are* initialized (that had nothing to do with fortran, so the alignment issues described above are not a factor), and therefore all linkers (including the OSX linker) will pull in this .o file and find all the symbols that it needs. 2. Do not initialize the C variables corresponding to the Fortran common blocks in the global scope. Indeed, never initialize them at all (because we never need their *values* - we only check for their *locations*). Since nothing is ever written to these variables (particularly in the global scope), the linker does not see any alignment differences during initialization, but does make both the C and Fortran variables have the same addresses (this method has been working in LAM/MPI for over a decade). There were some comments here in the OMPI code base and in the LAM code base that stated/implied that C variables corresponding to Fortran common blocks had to have the same alignment as the Fortran common blocks (i.e., 16). There were attempts in both code bases to ensure that this was true. However, the attempts were wrong (in both code bases), and I have now read enough Fortran compiler documentation to convince myself that matching alignments is not required (indeed, it's beyond our control). As long as C variables corresponding to Fortran common blocks are not initialized in the global scope, the linker will "figure it out" and adjust the alignment to whatever is required (i.e., the greater of the alignments). Specifically (to counter comments that no longer exist in the OMPI code base but still exist in the LAM code base): - there is no need to make attempts to specially align C variables corresponding to Fortran common blocks - the types and sizes of C variables corresponding to Fortran common blocks should match, but do not need to be on any particular alignment Finally, as a side effect of this effort, I found a bunch of inconsistencies with the intent of status/array_of_statuses parameters. For all the functions that I modified they should be "out" (not inout). This commit was SVN r11057.
2006-07-31 19:07:09 +04:00
/* Constants for the Fortran layer. These values are referred to via
common blocks in the Fortran equivalents. See
ompi/mpi/f77/constants.h for a more detailed explanation.
The values are *NOT* initialized. We do not use the values of
these constants; only their addresses (because they're always
passed by reference by Fortran).
Initializing upon instantiation these can reveal size and/or
alignment differences between Fortran and C (!) which can cause
warnings or errors upon linking (e.g., making static libraries with
the intel 9.0 compilers on 64 bit platforms shows alignment
differences between libmpi.a and the user's application, resulting
in a linker warning). FWIW, if you initialize these variables in
functions (i.e., not at the instantiation in the global scope), the
linker somehow "figures it all out" (w.r.t. different alignments
between fortan common blocks and the corresponding C variables) and
no linker warnings occur.
Note that the rationale for the types of each of these variables is
discussed in ompi/include/mpif-common.h. Do not change the types
without also modifying ompi/mpi/f77/constants.h and
ompi/include/mpif-common.h.
*/
#define INST(type, upper_case, lower_case, single_u, double_u) \
type lower_case; \
type upper_case; \
type single_u; \
type double_u
INST(int, MPI_FORTRAN_BOTTOM, mpi_fortran_bottom,
mpi_fortran_bottom_, mpi_fortran_bottom__);
INST(int, MPI_FORTRAN_IN_PLACE, mpi_fortran_in_place,
mpi_fortran_in_place_, mpi_fortran_in_place__);
INST(char *, MPI_FORTRAN_ARGV_NULL, mpi_fortran_argv_null,
mpi_fortran_argv_null_, mpi_fortran_argv_null__);
INST(double, MPI_FORTRAN_ARGVS_NULL, mpi_fortran_argvs_null,
mpi_fortran_argvs_null_, mpi_fortran_argvs_null__);
INST(int *, MPI_FORTRAN_ERRCODES_IGNORE, mpi_fortran_errcodes_ignore,
mpi_fortran_errcodes_ignore_, mpi_fortran_errcodes_ignore__);
INST(int *, MPI_FORTRAN_STATUS_IGNORE, mpi_fortran_status_ignore,
mpi_fortran_status_ignore_, mpi_fortran_status_ignore__);
INST (double, MPI_FORTRAN_STATUSES_IGNORE, mpi_fortran_statuses_ignore,
mpi_fortran_statuses_ignore_, mpi_fortran_statuses_ignore__);
/*
* Hash tables for MPI_Type_create_f90* functions
*/
opal_hash_table_t ompi_mpi_f90_integer_hashtable;
opal_hash_table_t ompi_mpi_f90_real_hashtable;
opal_hash_table_t ompi_mpi_f90_complex_hashtable;
/*
* Per MPI-2:9.5.3, MPI_REGISTER_DATAREP is a memory leak. There is
* no way to *de*register datareps once they've been registered. So
* we have to track all registrations here so that they can be
* de-registered during MPI_FINALIZE so that memory-tracking debuggers
* don't show Open MPI as leaking memory.
*/
opal_list_t ompi_registered_datareps;
Clean up the Fortran MPI sentinel values per problem reported on the users mailing list: http://www.open-mpi.org/community/lists/users/2006/07/1680.php Warning: this log message is not for the weak. Read at your own risk. The problem was that we had several variables in Fortran common blocks of various types, but their C counterparts were all of a type equivalent to a fortran double complex. This didn't seem to matter for the compilers that we tested, but we never tested static builds (which is where this problem seems to occur, at least with the Intel compiler: the linker compilains that the variable in the common block in the user's .o file was of one size/alignment but the one in the C library was a different size/alignment). So this patch fixes the sizes/types of the Fortran common block variables and their corresponding C instantiations to be of the same sizes/types. But wait, there's more. We recently introduced a fix for the OSX linker where some C versions of the fortran common block variables (e.g., _ompi_fortran_status_ignore) were not being found when linking ompi_info (!). Further research shows that the code path for ompi_info to require ompi_fortran_status_ignore is, unfortunately, necessary (a quirk of how various components pull in different portions of the code base -- nothing in ompi_info itself requires fortran or MPI knowledge, of course). Hence, the real problem was that there was no code path from ompi_info to the portion of the code base where the C globals corresponding to the Fortran common block variables were instantiated. This is because the OSX linker does not automatically pull in .o files that only contain unintialized global variables; the OSX linker typically only pulls in a .o file from a library if it either has a function that is used or have a global variable that is initialized (that's the short version; lots of details and corner cases omitted). Hence, we changed the global C variables corresponding to the fortran common blocks to be initialized, thereby causing the OSX linker to pull them in automatically -- problem solved. At the same time, we moved the constants to another .c file with a function, just for good measure. However, this didn't really solve the problem: 1. The function in the file with the C versions of the fortran common block variables (ompi/mpi/f77/test_constants_f.c) did not have a code path that was reachable from ompi_info, so the only reason that the constants were found (on OSX) was because they were initialized in the global scope (i.e., causing the OSX compiler to pull in that .o file). 2. Initializing these variable in the global scope causes problems for some linkers where -- once all the size/type problems mentioned above were fixed -- the alignments of fortran common blocks and C global variables do not match (even though the types of the Fortran and C variables match -- wow!). Hence, initializing the C variables would not necessarily match the alignment of what Fortran expected, and the linker would issue a warning (i.e., the alignment warnings referenced in the original post). The solution is two-fold: 1. Move the Fortran variables from test_constants_f.c to ompi/mpi/runtime/ompi_mpi_init.c where there are other global constants that *are* initialized (that had nothing to do with fortran, so the alignment issues described above are not a factor), and therefore all linkers (including the OSX linker) will pull in this .o file and find all the symbols that it needs. 2. Do not initialize the C variables corresponding to the Fortran common blocks in the global scope. Indeed, never initialize them at all (because we never need their *values* - we only check for their *locations*). Since nothing is ever written to these variables (particularly in the global scope), the linker does not see any alignment differences during initialization, but does make both the C and Fortran variables have the same addresses (this method has been working in LAM/MPI for over a decade). There were some comments here in the OMPI code base and in the LAM code base that stated/implied that C variables corresponding to Fortran common blocks had to have the same alignment as the Fortran common blocks (i.e., 16). There were attempts in both code bases to ensure that this was true. However, the attempts were wrong (in both code bases), and I have now read enough Fortran compiler documentation to convince myself that matching alignments is not required (indeed, it's beyond our control). As long as C variables corresponding to Fortran common blocks are not initialized in the global scope, the linker will "figure it out" and adjust the alignment to whatever is required (i.e., the greater of the alignments). Specifically (to counter comments that no longer exist in the OMPI code base but still exist in the LAM code base): - there is no need to make attempts to specially align C variables corresponding to Fortran common blocks - the types and sizes of C variables corresponding to Fortran common blocks should match, but do not need to be on any particular alignment Finally, as a side effect of this effort, I found a bunch of inconsistencies with the intent of status/array_of_statuses parameters. For all the functions that I modified they should be "out" (not inout). This commit was SVN r11057.
2006-07-31 19:07:09 +04:00
int ompi_mpi_init(int argc, char **argv, int requested, int *provided)
{
int ret;
ompi_proc_t** procs;
size_t nprocs;
char *error = NULL;
bool timing = false;
int param, value;
struct timeval ompistart, ompistop;
char *event_val = NULL;
opal_paffinity_base_cpu_set_t mask;
bool proc_bound;
#if 0
/* see comment below about sched_yield */
int num_processors;
#endif
bool orte_setup = false;
bool paffinity_enabled = false;
/* bitflag of the thread level support provided. To be used
* for the modex in order to work in heterogeneous environments. */
uint8_t threadlevel_bf;
/* Setup enough to check get/set MCA params */
if (ORTE_SUCCESS != (ret = opal_init_util(&argc, &argv))) {
error = "ompi_mpi_init: opal_init_util failed";
goto error;
}
/* _After_ opal_init_util() but _before_ orte_init(), we need to
set an MCA param that tells libevent that it's ok to use any
mechanism in libevent that is available on this platform (e.g.,
epoll and friends). Per opal/event/event.s, we default to
select/poll -- but we know that MPI processes won't be using
pty's with the event engine, so it's ok to relax this
constraint and let any fd-monitoring mechanism be used. */
ret = mca_base_param_reg_string_name("opal", "event_include",
"Internal orted MCA param: tell opal_init() to use a specific mechanism in libevent",
false, false, "all", &event_val);
if (ret >= 0) {
/* We have to explicitly "set" the MCA param value here
because libevent initialization will re-register the MCA
param and therefore override the default. Setting the value
here puts the desired value ("all") in different storage
that is not overwritten if/when the MCA param is
re-registered. This is unless the user has specified a different
value for this MCA parameter. Make sure we check to see if the
default is specified before forcing "all" in case that is not what
the user desires. Note that we do *NOT* set this value as an
environment variable, just so that it won't be inherited by
any spawned processes and potentially cause unintented
side-effects with launching ORTE tools... */
if (0 == strcmp("all", event_val)) {
mca_base_param_set_string(ret, "all");
}
}
if( NULL != event_val ) {
free(event_val);
event_val = NULL;
}
/* check to see if we want timing information */
param = mca_base_param_reg_int_name("ompi", "timing",
"Request that critical timing loops be measured",
false, false, 0, &value);
if (value != 0) {
timing = true;
gettimeofday(&ompistart, NULL);
}
/* Setup ORTE - note that we are an MPI process */
if (ORTE_SUCCESS != (ret = orte_init(NULL, NULL, ORTE_PROC_MPI))) {
These changes were mostly captured in a prior RFC (except for #2 below) and are aimed specifically at improving startup performance and setting up the remaining modifications described in that RFC. The commit has been tested for C/R and Cray operations, and on Odin (SLURM, rsh) and RoadRunner (TM). I tried to update all environments, but obviously could not test them. I know that Windows needs some work, and have highlighted what is know to be needed in the odls process component. This represents a lot of work by Brian, Tim P, Josh, and myself, with much advice from Jeff and others. For posterity, I have appended a copy of the email describing the work that was done: As we have repeatedly noted, the modex operation in MPI_Init is the single greatest consumer of time during startup. To-date, we have executed that operation as an ORTE stage gate that held the process until a startup message containing all required modex (and OOB contact info - see #3 below) info could be sent to it. Each process would send its data to the HNP's registry, which assembled and sent the message when all processes had reported in. In addition, ORTE had taken responsibility for monitoring process status as it progressed through a series of "stage gates". The process reported its status at each gate, and ORTE would then send a "release" message once all procs had reported in. The incoming changes revamp these procedures in three ways: 1. eliminating the ORTE stage gate system and cleanly delineating responsibility between the OMPI and ORTE layers for MPI init/finalize. The modex stage gate (STG1) has been replaced by a collective operation in the modex itself that performs an allgather on the required modex info. The allgather is implemented using the orte_grpcomm framework since the BTL's are not active at that point. At the moment, the grpcomm framework only has a "basic" component analogous to OMPI's "basic" coll framework - I would recommend that the MPI team create additional, more advanced components to improve performance of this step. The other stage gates have been replaced by orte_grpcomm barrier functions. We tried to use MPI barriers instead (since the BTL's are active at that point), but - as we discussed on the telecon - these are not currently true barriers so the job would hang when we fell through while messages were still in process. Note that the grpcomm barrier doesn't actually resolve that problem, but Brian has pointed out that we are unlikely to ever see it violated. Again, you might want to spend a little time on an advanced barrier algorithm as the one in "basic" is very simplistic. Summarizing this change: ORTE no longer tracks process state nor has direct responsibility for synchronizing jobs. This is now done via collective operations within the MPI layer, albeit using ORTE collective communication services. I -strongly- urge the MPI team to implement advanced collective algorithms to improve the performance of this critical procedure. 2. reducing the volume of data exchanged during modex. Data in the modex consisted of the process name, the name of the node where that process is located (expressed as a string), plus a string representation of all contact info. The nodename was required in order for the modex to determine if the process was local or not - in addition, some people like to have it to print pretty error messages when a connection failed. The size of this data has been reduced in three ways: (a) reducing the size of the process name itself. The process name consisted of two 32-bit fields for the jobid and vpid. This is far larger than any current system, or system likely to exist in the near future, can support. Accordingly, the default size of these fields has been reduced to 16-bits, which means you can have 32k procs in each of 32k jobs. Since the daemons must have a vpid, and we require one daemon/node, this also restricts the default configuration to 32k nodes. To support any future "mega-clusters", a configuration option --enable-jumbo-apps has been added. This option increases the jobid and vpid field sizes to 32-bits. Someday, if necessary, someone can add yet another option to increase them to 64-bits, I suppose. (b) replacing the string nodename with an integer nodeid. Since we have one daemon/node, the nodeid corresponds to the local daemon's vpid. This replaces an often lengthy string with only 2 (or at most 4) bytes, a substantial reduction. (c) when the mca param requesting that nodenames be sent to support pretty error messages, a second mca param is now used to request FQDN - otherwise, the domain name is stripped (by default) from the message to save space. If someone wants to combine those into a single param somehow (perhaps with an argument?), they are welcome to do so - I didn't want to alter what people are already using. While these may seem like small savings, they actually amount to a significant impact when aggregated across the entire modex operation. Since every proc must receive the modex data regardless of the collective used to send it, just reducing the size of the process name removes nearly 400MBytes of communication from a 32k proc job (admittedly, much of this comm may occur in parallel). So it does add up pretty quickly. 3. routing RML messages to reduce connections. The default messaging system remains point-to-point - i.e., each proc opens a socket to every proc it communicates with and sends its messages directly. A new option uses the orteds as routers - i.e., each proc only opens a single socket to its local orted. All messages are sent from the proc to the orted, which forwards the message to the orted on the node where the intended recipient proc is located - that orted then forwards the message to its local proc (the recipient). This greatly reduces the connection storm we have encountered during startup. It also has the benefit of removing the sharing of every proc's OOB contact with every other proc. The orted routing tables are populated during launch since every orted gets a map of where every proc is being placed. Each proc, therefore, only needs to know the contact info for its local daemon, which is passed in via the environment when the proc is fork/exec'd by the daemon. This alone removes ~50 bytes/process of communication that was in the current STG1 startup message - so for our 32k proc job, this saves us roughly 32k*50 = 1.6MBytes sent to 32k procs = 51GBytes of messaging. Note that you can use the new routing method by specifying -mca routed tree - if you so desire. This mode will become the default at some point in the future. There are a few minor additional changes in the commit that I'll just note in passing: * propagation of command line mca params to the orteds - fixes ticket #1073. See note there for details. * requiring of "finalize" prior to "exit" for MPI procs - fixes ticket #1144. See note there for details. * cleanup of some stale header files This commit was SVN r16364.
2007-10-05 23:48:23 +04:00
error = "ompi_mpi_init: orte_init failed";
goto error;
}
orte_setup = true;
These changes were mostly captured in a prior RFC (except for #2 below) and are aimed specifically at improving startup performance and setting up the remaining modifications described in that RFC. The commit has been tested for C/R and Cray operations, and on Odin (SLURM, rsh) and RoadRunner (TM). I tried to update all environments, but obviously could not test them. I know that Windows needs some work, and have highlighted what is know to be needed in the odls process component. This represents a lot of work by Brian, Tim P, Josh, and myself, with much advice from Jeff and others. For posterity, I have appended a copy of the email describing the work that was done: As we have repeatedly noted, the modex operation in MPI_Init is the single greatest consumer of time during startup. To-date, we have executed that operation as an ORTE stage gate that held the process until a startup message containing all required modex (and OOB contact info - see #3 below) info could be sent to it. Each process would send its data to the HNP's registry, which assembled and sent the message when all processes had reported in. In addition, ORTE had taken responsibility for monitoring process status as it progressed through a series of "stage gates". The process reported its status at each gate, and ORTE would then send a "release" message once all procs had reported in. The incoming changes revamp these procedures in three ways: 1. eliminating the ORTE stage gate system and cleanly delineating responsibility between the OMPI and ORTE layers for MPI init/finalize. The modex stage gate (STG1) has been replaced by a collective operation in the modex itself that performs an allgather on the required modex info. The allgather is implemented using the orte_grpcomm framework since the BTL's are not active at that point. At the moment, the grpcomm framework only has a "basic" component analogous to OMPI's "basic" coll framework - I would recommend that the MPI team create additional, more advanced components to improve performance of this step. The other stage gates have been replaced by orte_grpcomm barrier functions. We tried to use MPI barriers instead (since the BTL's are active at that point), but - as we discussed on the telecon - these are not currently true barriers so the job would hang when we fell through while messages were still in process. Note that the grpcomm barrier doesn't actually resolve that problem, but Brian has pointed out that we are unlikely to ever see it violated. Again, you might want to spend a little time on an advanced barrier algorithm as the one in "basic" is very simplistic. Summarizing this change: ORTE no longer tracks process state nor has direct responsibility for synchronizing jobs. This is now done via collective operations within the MPI layer, albeit using ORTE collective communication services. I -strongly- urge the MPI team to implement advanced collective algorithms to improve the performance of this critical procedure. 2. reducing the volume of data exchanged during modex. Data in the modex consisted of the process name, the name of the node where that process is located (expressed as a string), plus a string representation of all contact info. The nodename was required in order for the modex to determine if the process was local or not - in addition, some people like to have it to print pretty error messages when a connection failed. The size of this data has been reduced in three ways: (a) reducing the size of the process name itself. The process name consisted of two 32-bit fields for the jobid and vpid. This is far larger than any current system, or system likely to exist in the near future, can support. Accordingly, the default size of these fields has been reduced to 16-bits, which means you can have 32k procs in each of 32k jobs. Since the daemons must have a vpid, and we require one daemon/node, this also restricts the default configuration to 32k nodes. To support any future "mega-clusters", a configuration option --enable-jumbo-apps has been added. This option increases the jobid and vpid field sizes to 32-bits. Someday, if necessary, someone can add yet another option to increase them to 64-bits, I suppose. (b) replacing the string nodename with an integer nodeid. Since we have one daemon/node, the nodeid corresponds to the local daemon's vpid. This replaces an often lengthy string with only 2 (or at most 4) bytes, a substantial reduction. (c) when the mca param requesting that nodenames be sent to support pretty error messages, a second mca param is now used to request FQDN - otherwise, the domain name is stripped (by default) from the message to save space. If someone wants to combine those into a single param somehow (perhaps with an argument?), they are welcome to do so - I didn't want to alter what people are already using. While these may seem like small savings, they actually amount to a significant impact when aggregated across the entire modex operation. Since every proc must receive the modex data regardless of the collective used to send it, just reducing the size of the process name removes nearly 400MBytes of communication from a 32k proc job (admittedly, much of this comm may occur in parallel). So it does add up pretty quickly. 3. routing RML messages to reduce connections. The default messaging system remains point-to-point - i.e., each proc opens a socket to every proc it communicates with and sends its messages directly. A new option uses the orteds as routers - i.e., each proc only opens a single socket to its local orted. All messages are sent from the proc to the orted, which forwards the message to the orted on the node where the intended recipient proc is located - that orted then forwards the message to its local proc (the recipient). This greatly reduces the connection storm we have encountered during startup. It also has the benefit of removing the sharing of every proc's OOB contact with every other proc. The orted routing tables are populated during launch since every orted gets a map of where every proc is being placed. Each proc, therefore, only needs to know the contact info for its local daemon, which is passed in via the environment when the proc is fork/exec'd by the daemon. This alone removes ~50 bytes/process of communication that was in the current STG1 startup message - so for our 32k proc job, this saves us roughly 32k*50 = 1.6MBytes sent to 32k procs = 51GBytes of messaging. Note that you can use the new routing method by specifying -mca routed tree - if you so desire. This mode will become the default at some point in the future. There are a few minor additional changes in the commit that I'll just note in passing: * propagation of command line mca params to the orteds - fixes ticket #1073. See note there for details. * requiring of "finalize" prior to "exit" for MPI procs - fixes ticket #1144. See note there for details. * cleanup of some stale header files This commit was SVN r16364.
2007-10-05 23:48:23 +04:00
/* check for timing request - get stop time and report elapsed time if so */
if (timing && 0 == ORTE_PROC_MY_NAME->vpid) {
gettimeofday(&ompistop, NULL);
opal_output(0, "ompi_mpi_init [%ld]: time from start to completion of orte_init %ld usec",
(long)ORTE_PROC_MY_NAME->vpid,
(long int)((ompistop.tv_sec - ompistart.tv_sec)*1000000 +
(ompistop.tv_usec - ompistart.tv_usec)));
gettimeofday(&ompistart, NULL);
}
/* Figure out the final MPI thread levels. If we were not
compiled for support for MPI threads, then don't allow
MPI_THREAD_MULTIPLE. Set this stuff up here early in the
process so that other components can make decisions based on
this value. */
ompi_mpi_thread_requested = requested;
if (OPAL_HAVE_THREAD_SUPPORT == 0) {
ompi_mpi_thread_provided = *provided = MPI_THREAD_SINGLE;
ompi_mpi_main_thread = NULL;
} else if (OPAL_ENABLE_MPI_THREADS == 1) {
ompi_mpi_thread_provided = *provided = requested;
ompi_mpi_main_thread = opal_thread_get_self();
} else {
if (MPI_THREAD_MULTIPLE == requested) {
ompi_mpi_thread_provided = *provided = MPI_THREAD_SERIALIZED;
} else {
ompi_mpi_thread_provided = *provided = requested;
}
ompi_mpi_main_thread = opal_thread_get_self();
}
ompi_mpi_thread_multiple = (ompi_mpi_thread_provided ==
MPI_THREAD_MULTIPLE);
/* determine the bitflag belonging to the threadlevel_support provided */
memset ( &threadlevel_bf, 0, sizeof(uint8_t));
OMPI_THREADLEVEL_SET_BITFLAG ( ompi_mpi_thread_provided, threadlevel_bf );
/* add this bitflag to the modex */
if ( OMPI_SUCCESS != (ret = ompi_modex_send_string("MPI_THREAD_LEVEL", &threadlevel_bf, sizeof(uint8_t)))) {
error = "ompi_mpi_init: modex send thread level";
goto error;
}
/* Once we've joined the RTE, see if any MCA parameters were
passed to the MPI level */
if (OMPI_SUCCESS != (ret = ompi_mpi_register_params())) {
error = "mca_mpi_register_params() failed";
goto error;
}
/* If desired, send a notify message */
if (ompi_notify_init_finalize) {
orte_notifier.log(ORTE_NOTIFIER_NOTICE,
ORTE_SUCCESS,
"MPI_INIT:Starting on host %s, pid %d",
orte_process_info.nodename,
orte_process_info.pid);
}
/* if it hasn't already been done, setup process affinity.
* First check to see if a slot list was
* specified. If so, use it. If no slot list was specified,
* that's not an error -- just fall through and try the next
* paffinity scheme.
*/
ret = opal_paffinity_base_get(&mask);
if (OPAL_SUCCESS == ret) {
/* paffinity is supported - check for binding */
OPAL_PAFFINITY_PROCESS_IS_BOUND(mask, &proc_bound);
if (proc_bound) {
/* someone external set it - indicate it is set
* so that we know
*/
paffinity_enabled = true;
} else {
/* the system is capable of doing processor affinity, but it
* has not yet been set - see if a slot_list was given
*/
if (NULL != opal_paffinity_base_slot_list) {
/* It's an error if multiple paffinity schemes were specified */
if (opal_paffinity_alone) {
ret = OMPI_ERR_BAD_PARAM;
error = "Multiple processor affinity schemes specified (can only specify one)";
goto error;
}
ret = opal_paffinity_base_slot_list_set((long)ORTE_PROC_MY_NAME->vpid, opal_paffinity_base_slot_list);
if (OPAL_SUCCESS != ret && OPAL_ERR_NOT_FOUND != ret) {
error = "opal_paffinity_base_slot_list_set() returned an error";
goto error;
}
paffinity_enabled = true;
} else if (opal_paffinity_alone) {
/* no slot_list, but they asked for paffinity */
int phys_cpu;
orte_node_rank_t nrank;
if (ORTE_NODE_RANK_INVALID == (nrank = orte_ess.get_node_rank(ORTE_PROC_MY_NAME))) {
ret = OMPI_ERR_BAD_PARAM;
error = "Could not get node rank - cannot set processor affinity";
goto error;
}
OPAL_PAFFINITY_CPU_ZERO(mask);
phys_cpu = opal_paffinity_base_get_physical_processor_id(nrank);
if (0 > phys_cpu) {
ret = phys_cpu;
error = "Could not get physical processor id - cannot set processor affinity";
goto error;
}
OPAL_PAFFINITY_CPU_SET(phys_cpu, mask);
ret = opal_paffinity_base_set(mask);
if (OPAL_SUCCESS != ret) {
error = "Setting processor affinity failed";
goto error;
}
paffinity_enabled = true;
}
}
}
/* If we were able to set processor affinity, try setting up
memory affinity */
if (!opal_maffinity_setup && paffinity_enabled) {
if (OPAL_SUCCESS == opal_maffinity_base_open() &&
OPAL_SUCCESS == opal_maffinity_base_select()) {
opal_maffinity_setup = true;
}
}
/* initialize datatypes. This step should be done early as it will
* create the local convertor and local arch used in the proc
* init.
*/
if (OMPI_SUCCESS != (ret = ompi_datatype_init())) {
error = "ompi_datatype_init() failed";
goto error;
}
/* Initialize OMPI procs */
if (OMPI_SUCCESS != (ret = ompi_proc_init())) {
error = "mca_proc_init() failed";
goto error;
}
Two major things in this commit: * New "op" MPI layer framework * Addition of the MPI_REDUCE_LOCAL proposed function (for MPI-2.2) = Op framework = Add new "op" framework in the ompi layer. This framework replaces the hard-coded MPI_Op back-end functions for (MPI_Op, MPI_Datatype) tuples for pre-defined MPI_Ops, allowing components and modules to provide the back-end functions. The intent is that components can be written to take advantage of hardware acceleration (GPU, FPGA, specialized CPU instructions, etc.). Similar to other frameworks, components are intended to be able to discover at run-time if they can be used, and if so, elect themselves to be selected (or disqualify themselves from selection if they cannot run). If specialized hardware is not available, there is a default set of functions that will automatically be used. This framework is ''not'' used for user-defined MPI_Ops. The new op framework is similar to the existing coll framework, in that the final set of function pointers that are used on any given intrinsic MPI_Op can be a mixed bag of function pointers, potentially coming from multiple different op modules. This allows for hardware that only supports some of the operations, not all of them (e.g., a GPU that only supports single-precision operations). All the hard-coded back-end MPI_Op functions for (MPI_Op, MPI_Datatype) tuples still exist, but unlike coll, they're in the framework base (vs. being in a separate "basic" component) and are automatically used if no component is found at runtime that provides a module with the necessary function pointers. There is an "example" op component that will hopefully be useful to those writing meaningful op components. It is currently .ompi_ignore'd so that it doesn't impinge on other developers (it's somewhat chatty in terms of opal_output() so that you can tell when its functions have been invoked). See the README file in the example op component directory. Developers of new op components are encouraged to look at the following wiki pages: https://svn.open-mpi.org/trac/ompi/wiki/devel/Autogen https://svn.open-mpi.org/trac/ompi/wiki/devel/CreateComponent https://svn.open-mpi.org/trac/ompi/wiki/devel/CreateFramework = MPI_REDUCE_LOCAL = Part of the MPI-2.2 proposal listed here: https://svn.mpi-forum.org/trac/mpi-forum-web/ticket/24 is to add a new function named MPI_REDUCE_LOCAL. It is very easy to implement, so I added it (also because it makes testing the op framework pretty easy -- you can do it in serial rather than via parallel reductions). There's even a man page! This commit was SVN r20280.
2009-01-15 02:44:31 +03:00
/* Initialize the op framework. This has to be done *after*
ddt_init, but befor mca_coll_base_open, since some collective
modules (e.g., the hierarchical coll component) may need ops in
their query function. */
if (OMPI_SUCCESS != (ret = ompi_op_base_open())) {
error = "ompi_op_base_open() failed";
goto error;
}
if (OMPI_SUCCESS !=
(ret = ompi_op_base_find_available(OPAL_ENABLE_PROGRESS_THREADS,
OPAL_ENABLE_MPI_THREADS))) {
Two major things in this commit: * New "op" MPI layer framework * Addition of the MPI_REDUCE_LOCAL proposed function (for MPI-2.2) = Op framework = Add new "op" framework in the ompi layer. This framework replaces the hard-coded MPI_Op back-end functions for (MPI_Op, MPI_Datatype) tuples for pre-defined MPI_Ops, allowing components and modules to provide the back-end functions. The intent is that components can be written to take advantage of hardware acceleration (GPU, FPGA, specialized CPU instructions, etc.). Similar to other frameworks, components are intended to be able to discover at run-time if they can be used, and if so, elect themselves to be selected (or disqualify themselves from selection if they cannot run). If specialized hardware is not available, there is a default set of functions that will automatically be used. This framework is ''not'' used for user-defined MPI_Ops. The new op framework is similar to the existing coll framework, in that the final set of function pointers that are used on any given intrinsic MPI_Op can be a mixed bag of function pointers, potentially coming from multiple different op modules. This allows for hardware that only supports some of the operations, not all of them (e.g., a GPU that only supports single-precision operations). All the hard-coded back-end MPI_Op functions for (MPI_Op, MPI_Datatype) tuples still exist, but unlike coll, they're in the framework base (vs. being in a separate "basic" component) and are automatically used if no component is found at runtime that provides a module with the necessary function pointers. There is an "example" op component that will hopefully be useful to those writing meaningful op components. It is currently .ompi_ignore'd so that it doesn't impinge on other developers (it's somewhat chatty in terms of opal_output() so that you can tell when its functions have been invoked). See the README file in the example op component directory. Developers of new op components are encouraged to look at the following wiki pages: https://svn.open-mpi.org/trac/ompi/wiki/devel/Autogen https://svn.open-mpi.org/trac/ompi/wiki/devel/CreateComponent https://svn.open-mpi.org/trac/ompi/wiki/devel/CreateFramework = MPI_REDUCE_LOCAL = Part of the MPI-2.2 proposal listed here: https://svn.mpi-forum.org/trac/mpi-forum-web/ticket/24 is to add a new function named MPI_REDUCE_LOCAL. It is very easy to implement, so I added it (also because it makes testing the op framework pretty easy -- you can do it in serial rather than via parallel reductions). There's even a man page! This commit was SVN r20280.
2009-01-15 02:44:31 +03:00
error = "ompi_op_base_find_available() failed";
goto error;
}
if (OMPI_SUCCESS != (ret = ompi_op_init())) {
error = "ompi_op_init() failed";
goto error;
}
/* Open up MPI-related MCA components */
if (OMPI_SUCCESS != (ret = mca_allocator_base_open())) {
error = "mca_allocator_base_open() failed";
goto error;
}
if (OMPI_SUCCESS != (ret = mca_rcache_base_open())) {
error = "mca_rcache_base_open() failed";
goto error;
}
if (OMPI_SUCCESS != (ret = mca_mpool_base_open())) {
error = "mca_mpool_base_open() failed";
goto error;
}
if (OMPI_SUCCESS != (ret = mca_pml_base_open())) {
error = "mca_pml_base_open() failed";
goto error;
}
if (OMPI_SUCCESS != (ret = mca_coll_base_open())) {
error = "mca_coll_base_open() failed";
goto error;
}
if (OMPI_SUCCESS != (ret = ompi_osc_base_open())) {
error = "ompi_osc_base_open() failed";
goto error;
}
#if OPAL_ENABLE_FT == 1
if (OMPI_SUCCESS != (ret = ompi_crcp_base_open())) {
error = "ompi_crcp_base_open() failed";
goto error;
}
#endif
/* In order to reduce the common case for MPI apps (where they
don't use MPI-2 IO or MPI-1 topology functions), the io and
topo frameworks are initialized lazily, at the first use of
relevant functions (e.g., MPI_FILE_*, MPI_CART_*, MPI_GRAPH_*),
so they are not opened here. */
/* Select which MPI components to use */
if (OMPI_SUCCESS !=
(ret = mca_mpool_base_init(OPAL_ENABLE_PROGRESS_THREADS,
OPAL_ENABLE_MPI_THREADS))) {
error = "mca_mpool_base_init() failed";
goto error;
}
if (OMPI_SUCCESS !=
(ret = mca_pml_base_select(OPAL_ENABLE_PROGRESS_THREADS,
OPAL_ENABLE_MPI_THREADS))) {
error = "mca_pml_base_select() failed";
goto error;
}
/* select buffered send allocator component to be used */
ret=mca_pml_base_bsend_init(OPAL_ENABLE_MPI_THREADS);
if( OMPI_SUCCESS != ret ) {
error = "mca_pml_base_bsend_init() failed";
goto error;
}
if (OMPI_SUCCESS !=
(ret = mca_coll_base_find_available(OPAL_ENABLE_PROGRESS_THREADS,
OPAL_ENABLE_MPI_THREADS))) {
error = "mca_coll_base_find_available() failed";
goto error;
}
if (OMPI_SUCCESS !=
(ret = ompi_osc_base_find_available(OPAL_ENABLE_PROGRESS_THREADS,
OPAL_ENABLE_MPI_THREADS))) {
error = "ompi_osc_base_find_available() failed";
goto error;
}
#if OPAL_ENABLE_FT == 1
if (OMPI_SUCCESS != (ret = ompi_crcp_base_select() ) ) {
error = "ompi_crcp_base_select() failed";
goto error;
}
#endif
/* io and topo components are not selected here -- see comment
above about the io and topo frameworks being loaded lazily */
/* Initialize each MPI handle subsystem */
/* initialize requests */
if (OMPI_SUCCESS != (ret = ompi_request_init())) {
error = "ompi_request_init() failed";
goto error;
}
/* initialize info */
if (OMPI_SUCCESS != (ret = ompi_info_init())) {
error = "ompi_info_init() failed";
goto error;
}
/* initialize error handlers */
if (OMPI_SUCCESS != (ret = ompi_errhandler_init())) {
error = "ompi_errhandler_init() failed";
goto error;
}
/* initialize error codes */
if (OMPI_SUCCESS != (ret = ompi_mpi_errcode_init())) {
error = "ompi_mpi_errcode_init() failed";
goto error;
}
/* initialize internal error codes */
if (OMPI_SUCCESS != (ret = ompi_errcode_intern_init())) {
error = "ompi_errcode_intern_init() failed";
goto error;
}
/* initialize groups */
if (OMPI_SUCCESS != (ret = ompi_group_init())) {
error = "ompi_group_init() failed";
goto error;
}
/* initialize communicators */
if (OMPI_SUCCESS != (ret = ompi_comm_init())) {
error = "ompi_comm_init() failed";
goto error;
}
/* initialize file handles */
if (OMPI_SUCCESS != (ret = ompi_file_init())) {
error = "ompi_file_init() failed";
goto error;
}
/* initialize windows */
if (OMPI_SUCCESS != (ret = ompi_win_init())) {
error = "ompi_win_init() failed";
goto error;
}
/* initialize attribute meta-data structure for comm/win/dtype */
if (OMPI_SUCCESS != (ret = ompi_attr_init())) {
error = "ompi_attr_init() failed";
goto error;
}
/* check for timing request - get stop time and report elapsed time if so */
if (timing && 0 == ORTE_PROC_MY_NAME->vpid) {
gettimeofday(&ompistop, NULL);
opal_output(0, "ompi_mpi_init[%ld]: time from completion of orte_init to modex %ld usec",
(long)ORTE_PROC_MY_NAME->vpid,
(long int)((ompistop.tv_sec - ompistart.tv_sec)*1000000 +
(ompistop.tv_usec - ompistart.tv_usec)));
gettimeofday(&ompistart, NULL);
}
/* exchange connection info - this function also acts as a barrier
These changes were mostly captured in a prior RFC (except for #2 below) and are aimed specifically at improving startup performance and setting up the remaining modifications described in that RFC. The commit has been tested for C/R and Cray operations, and on Odin (SLURM, rsh) and RoadRunner (TM). I tried to update all environments, but obviously could not test them. I know that Windows needs some work, and have highlighted what is know to be needed in the odls process component. This represents a lot of work by Brian, Tim P, Josh, and myself, with much advice from Jeff and others. For posterity, I have appended a copy of the email describing the work that was done: As we have repeatedly noted, the modex operation in MPI_Init is the single greatest consumer of time during startup. To-date, we have executed that operation as an ORTE stage gate that held the process until a startup message containing all required modex (and OOB contact info - see #3 below) info could be sent to it. Each process would send its data to the HNP's registry, which assembled and sent the message when all processes had reported in. In addition, ORTE had taken responsibility for monitoring process status as it progressed through a series of "stage gates". The process reported its status at each gate, and ORTE would then send a "release" message once all procs had reported in. The incoming changes revamp these procedures in three ways: 1. eliminating the ORTE stage gate system and cleanly delineating responsibility between the OMPI and ORTE layers for MPI init/finalize. The modex stage gate (STG1) has been replaced by a collective operation in the modex itself that performs an allgather on the required modex info. The allgather is implemented using the orte_grpcomm framework since the BTL's are not active at that point. At the moment, the grpcomm framework only has a "basic" component analogous to OMPI's "basic" coll framework - I would recommend that the MPI team create additional, more advanced components to improve performance of this step. The other stage gates have been replaced by orte_grpcomm barrier functions. We tried to use MPI barriers instead (since the BTL's are active at that point), but - as we discussed on the telecon - these are not currently true barriers so the job would hang when we fell through while messages were still in process. Note that the grpcomm barrier doesn't actually resolve that problem, but Brian has pointed out that we are unlikely to ever see it violated. Again, you might want to spend a little time on an advanced barrier algorithm as the one in "basic" is very simplistic. Summarizing this change: ORTE no longer tracks process state nor has direct responsibility for synchronizing jobs. This is now done via collective operations within the MPI layer, albeit using ORTE collective communication services. I -strongly- urge the MPI team to implement advanced collective algorithms to improve the performance of this critical procedure. 2. reducing the volume of data exchanged during modex. Data in the modex consisted of the process name, the name of the node where that process is located (expressed as a string), plus a string representation of all contact info. The nodename was required in order for the modex to determine if the process was local or not - in addition, some people like to have it to print pretty error messages when a connection failed. The size of this data has been reduced in three ways: (a) reducing the size of the process name itself. The process name consisted of two 32-bit fields for the jobid and vpid. This is far larger than any current system, or system likely to exist in the near future, can support. Accordingly, the default size of these fields has been reduced to 16-bits, which means you can have 32k procs in each of 32k jobs. Since the daemons must have a vpid, and we require one daemon/node, this also restricts the default configuration to 32k nodes. To support any future "mega-clusters", a configuration option --enable-jumbo-apps has been added. This option increases the jobid and vpid field sizes to 32-bits. Someday, if necessary, someone can add yet another option to increase them to 64-bits, I suppose. (b) replacing the string nodename with an integer nodeid. Since we have one daemon/node, the nodeid corresponds to the local daemon's vpid. This replaces an often lengthy string with only 2 (or at most 4) bytes, a substantial reduction. (c) when the mca param requesting that nodenames be sent to support pretty error messages, a second mca param is now used to request FQDN - otherwise, the domain name is stripped (by default) from the message to save space. If someone wants to combine those into a single param somehow (perhaps with an argument?), they are welcome to do so - I didn't want to alter what people are already using. While these may seem like small savings, they actually amount to a significant impact when aggregated across the entire modex operation. Since every proc must receive the modex data regardless of the collective used to send it, just reducing the size of the process name removes nearly 400MBytes of communication from a 32k proc job (admittedly, much of this comm may occur in parallel). So it does add up pretty quickly. 3. routing RML messages to reduce connections. The default messaging system remains point-to-point - i.e., each proc opens a socket to every proc it communicates with and sends its messages directly. A new option uses the orteds as routers - i.e., each proc only opens a single socket to its local orted. All messages are sent from the proc to the orted, which forwards the message to the orted on the node where the intended recipient proc is located - that orted then forwards the message to its local proc (the recipient). This greatly reduces the connection storm we have encountered during startup. It also has the benefit of removing the sharing of every proc's OOB contact with every other proc. The orted routing tables are populated during launch since every orted gets a map of where every proc is being placed. Each proc, therefore, only needs to know the contact info for its local daemon, which is passed in via the environment when the proc is fork/exec'd by the daemon. This alone removes ~50 bytes/process of communication that was in the current STG1 startup message - so for our 32k proc job, this saves us roughly 32k*50 = 1.6MBytes sent to 32k procs = 51GBytes of messaging. Note that you can use the new routing method by specifying -mca routed tree - if you so desire. This mode will become the default at some point in the future. There are a few minor additional changes in the commit that I'll just note in passing: * propagation of command line mca params to the orteds - fixes ticket #1073. See note there for details. * requiring of "finalize" prior to "exit" for MPI procs - fixes ticket #1144. See note there for details. * cleanup of some stale header files This commit was SVN r16364.
2007-10-05 23:48:23 +04:00
* as it will not return until the exchange is complete
*/
if (OMPI_SUCCESS != (ret = orte_grpcomm.modex(NULL))) {
error = "orte_grpcomm_modex failed";
goto error;
}
if (timing && 0 == ORTE_PROC_MY_NAME->vpid) {
gettimeofday(&ompistop, NULL);
opal_output(0, "ompi_mpi_init[%ld]: time to execute modex %ld usec",
(long)ORTE_PROC_MY_NAME->vpid,
(long int)((ompistop.tv_sec - ompistart.tv_sec)*1000000 +
(ompistop.tv_usec - ompistart.tv_usec)));
gettimeofday(&ompistart, NULL);
}
These changes were mostly captured in a prior RFC (except for #2 below) and are aimed specifically at improving startup performance and setting up the remaining modifications described in that RFC. The commit has been tested for C/R and Cray operations, and on Odin (SLURM, rsh) and RoadRunner (TM). I tried to update all environments, but obviously could not test them. I know that Windows needs some work, and have highlighted what is know to be needed in the odls process component. This represents a lot of work by Brian, Tim P, Josh, and myself, with much advice from Jeff and others. For posterity, I have appended a copy of the email describing the work that was done: As we have repeatedly noted, the modex operation in MPI_Init is the single greatest consumer of time during startup. To-date, we have executed that operation as an ORTE stage gate that held the process until a startup message containing all required modex (and OOB contact info - see #3 below) info could be sent to it. Each process would send its data to the HNP's registry, which assembled and sent the message when all processes had reported in. In addition, ORTE had taken responsibility for monitoring process status as it progressed through a series of "stage gates". The process reported its status at each gate, and ORTE would then send a "release" message once all procs had reported in. The incoming changes revamp these procedures in three ways: 1. eliminating the ORTE stage gate system and cleanly delineating responsibility between the OMPI and ORTE layers for MPI init/finalize. The modex stage gate (STG1) has been replaced by a collective operation in the modex itself that performs an allgather on the required modex info. The allgather is implemented using the orte_grpcomm framework since the BTL's are not active at that point. At the moment, the grpcomm framework only has a "basic" component analogous to OMPI's "basic" coll framework - I would recommend that the MPI team create additional, more advanced components to improve performance of this step. The other stage gates have been replaced by orte_grpcomm barrier functions. We tried to use MPI barriers instead (since the BTL's are active at that point), but - as we discussed on the telecon - these are not currently true barriers so the job would hang when we fell through while messages were still in process. Note that the grpcomm barrier doesn't actually resolve that problem, but Brian has pointed out that we are unlikely to ever see it violated. Again, you might want to spend a little time on an advanced barrier algorithm as the one in "basic" is very simplistic. Summarizing this change: ORTE no longer tracks process state nor has direct responsibility for synchronizing jobs. This is now done via collective operations within the MPI layer, albeit using ORTE collective communication services. I -strongly- urge the MPI team to implement advanced collective algorithms to improve the performance of this critical procedure. 2. reducing the volume of data exchanged during modex. Data in the modex consisted of the process name, the name of the node where that process is located (expressed as a string), plus a string representation of all contact info. The nodename was required in order for the modex to determine if the process was local or not - in addition, some people like to have it to print pretty error messages when a connection failed. The size of this data has been reduced in three ways: (a) reducing the size of the process name itself. The process name consisted of two 32-bit fields for the jobid and vpid. This is far larger than any current system, or system likely to exist in the near future, can support. Accordingly, the default size of these fields has been reduced to 16-bits, which means you can have 32k procs in each of 32k jobs. Since the daemons must have a vpid, and we require one daemon/node, this also restricts the default configuration to 32k nodes. To support any future "mega-clusters", a configuration option --enable-jumbo-apps has been added. This option increases the jobid and vpid field sizes to 32-bits. Someday, if necessary, someone can add yet another option to increase them to 64-bits, I suppose. (b) replacing the string nodename with an integer nodeid. Since we have one daemon/node, the nodeid corresponds to the local daemon's vpid. This replaces an often lengthy string with only 2 (or at most 4) bytes, a substantial reduction. (c) when the mca param requesting that nodenames be sent to support pretty error messages, a second mca param is now used to request FQDN - otherwise, the domain name is stripped (by default) from the message to save space. If someone wants to combine those into a single param somehow (perhaps with an argument?), they are welcome to do so - I didn't want to alter what people are already using. While these may seem like small savings, they actually amount to a significant impact when aggregated across the entire modex operation. Since every proc must receive the modex data regardless of the collective used to send it, just reducing the size of the process name removes nearly 400MBytes of communication from a 32k proc job (admittedly, much of this comm may occur in parallel). So it does add up pretty quickly. 3. routing RML messages to reduce connections. The default messaging system remains point-to-point - i.e., each proc opens a socket to every proc it communicates with and sends its messages directly. A new option uses the orteds as routers - i.e., each proc only opens a single socket to its local orted. All messages are sent from the proc to the orted, which forwards the message to the orted on the node where the intended recipient proc is located - that orted then forwards the message to its local proc (the recipient). This greatly reduces the connection storm we have encountered during startup. It also has the benefit of removing the sharing of every proc's OOB contact with every other proc. The orted routing tables are populated during launch since every orted gets a map of where every proc is being placed. Each proc, therefore, only needs to know the contact info for its local daemon, which is passed in via the environment when the proc is fork/exec'd by the daemon. This alone removes ~50 bytes/process of communication that was in the current STG1 startup message - so for our 32k proc job, this saves us roughly 32k*50 = 1.6MBytes sent to 32k procs = 51GBytes of messaging. Note that you can use the new routing method by specifying -mca routed tree - if you so desire. This mode will become the default at some point in the future. There are a few minor additional changes in the commit that I'll just note in passing: * propagation of command line mca params to the orteds - fixes ticket #1073. See note there for details. * requiring of "finalize" prior to "exit" for MPI procs - fixes ticket #1144. See note there for details. * cleanup of some stale header files This commit was SVN r16364.
2007-10-05 23:48:23 +04:00
/* identify the architectures of remote procs and setup
* their datatype convertors, if required
*/
if (OMPI_SUCCESS != (ret = ompi_proc_set_arch())) {
error = "ompi_proc_set_arch failed";
goto error;
}
/* If thread support was enabled, then setup OPAL to allow for
them. */
if ((OPAL_ENABLE_PROGRESS_THREADS == 1) ||
(*provided != MPI_THREAD_SINGLE)) {
opal_set_using_threads(true);
}
/* start PML/BTL's */
ret = MCA_PML_CALL(enable(true));
if( OMPI_SUCCESS != ret ) {
error = "PML control failed";
goto error;
}
/* add all ompi_proc_t's to PML */
if (NULL == (procs = ompi_proc_world(&nprocs))) {
error = "ompi_proc_world() failed";
goto error;
}
ret = MCA_PML_CALL(add_procs(procs, nprocs));
free(procs);
if( OMPI_SUCCESS != ret ) {
error = "PML add procs failed";
goto error;
}
MCA_PML_CALL(add_comm(&ompi_mpi_comm_world.comm));
MCA_PML_CALL(add_comm(&ompi_mpi_comm_self.comm));
/*
* Dump all MCA parameters if requested
*/
if (ompi_mpi_show_mca_params) {
ompi_show_all_mca_params(ompi_mpi_comm_world.comm.c_my_rank,
nprocs,
orte_process_info.nodename);
}
/* Do we need to wait for a debugger? */
ompi_wait_for_debugger();
/* check for timing request - get stop time and report elapsed
time if so, then start the clock again */
if (timing && 0 == ORTE_PROC_MY_NAME->vpid) {
gettimeofday(&ompistop, NULL);
opal_output(0, "ompi_mpi_init[%ld]: time from modex to first barrier %ld usec",
(long)ORTE_PROC_MY_NAME->vpid,
(long int)((ompistop.tv_sec - ompistart.tv_sec)*1000000 +
(ompistop.tv_usec - ompistart.tv_usec)));
gettimeofday(&ompistart, NULL);
}
/* wait for everyone to reach this point */
if (OMPI_SUCCESS != (ret = orte_grpcomm.barrier())) {
error = "orte_grpcomm_barrier failed";
goto error;
}
/* check for timing request - get stop time and report elapsed
time if so, then start the clock again */
if (timing && 0 == ORTE_PROC_MY_NAME->vpid) {
gettimeofday(&ompistop, NULL);
opal_output(0, "ompi_mpi_init[%ld]: time to execute barrier %ld usec",
(long)ORTE_PROC_MY_NAME->vpid,
(long int)((ompistop.tv_sec - ompistart.tv_sec)*1000000 +
(ompistop.tv_usec - ompistart.tv_usec)));
gettimeofday(&ompistart, NULL);
}
#if OPAL_ENABLE_PROGRESS_THREADS == 0
/* Start setting up the event engine for MPI operations. Don't
block in the event library, so that communications don't take
forever between procs in the dynamic code. This will increase
CPU utilization for the remainder of MPI_INIT when we are
blocking on ORTE-level events, but may greatly reduce non-TCP
latency. */
opal_progress_set_event_flag(OPAL_EVLOOP_NONBLOCK);
#endif
/* wire up the mpi interface, if requested. Do this after the
non-block switch for non-TCP performance. Do before the
polling change as anyone with a complex wire-up is going to be
using the oob. */
if (OMPI_SUCCESS != (ret = ompi_init_preconnect_mpi())) {
error = "ompi_mpi_do_preconnect_all() failed";
goto error;
}
/* Setup the publish/subscribe (PUBSUB) framework */
if (OMPI_SUCCESS != (ret = ompi_pubsub_base_open())) {
error = "ompi_pubsub_base_open() failed";
goto error;
}
if (OMPI_SUCCESS != (ret = ompi_pubsub_base_select())) {
error = "ompi_pubsub_base_select() failed";
goto error;
}
/* Setup the dynamic process management (DPM) framework */
if (OMPI_SUCCESS != (ret = ompi_dpm_base_open())) {
error = "ompi_dpm_base_open() failed";
goto error;
}
if (OMPI_SUCCESS != (ret = ompi_dpm_base_select())) {
error = "ompi_dpm_base_select() failed";
goto error;
}
/* Determine the overall threadlevel support of all processes
in MPI_COMM_WORLD. This has to be done before calling
coll_base_comm_select, since some of the collective components
e.g. hierarch, might create subcommunicators. The threadlevel
requested by all processes is required in order to know
which cid allocation algorithm can be used. */
if ( OMPI_SUCCESS !=
( ret = ompi_comm_cid_init ())) {
error = "ompi_mpi_init: ompi_comm_cid_init failed";
goto error;
}
/* Init coll for the comms. This has to be after dpm_base_select,
(since dpm.mark_dyncomm is not set in the communicator creation
function else), but before dpm.dyncom_init, since this function
might require collective for the CID allocation. */
if (OMPI_SUCCESS !=
(ret = mca_coll_base_comm_select(MPI_COMM_WORLD))) {
error = "mca_coll_base_comm_select(MPI_COMM_WORLD) failed";
goto error;
}
if (OMPI_SUCCESS !=
(ret = mca_coll_base_comm_select(MPI_COMM_SELF))) {
error = "mca_coll_base_comm_select(MPI_COMM_SELF) failed";
goto error;
}
/* Check whether we have been spawned or not. We introduce that
at the very end, since we need collectives, datatypes, ptls
etc. up and running here.... */
if (OMPI_SUCCESS != (ret = ompi_dpm.dyn_init())) {
error = "ompi_comm_dyn_init() failed";
goto error;
}
/*
* Startup the Checkpoint/Restart Mech.
* Note: Always do this so tools don't hang when
* in a non-checkpointable build
*/
if (OMPI_SUCCESS != (ret = ompi_cr_init())) {
error = "ompi_cr_init";
goto error;
}
/* Undo ORTE calling opal_progress_event_users_increment() during
MPI lifetime, to get better latency when not using TCP. Do
this *after* dyn_init, as dyn init uses lots of ORTE
communication and we don't want to hinder the performance of
that code. */
opal_progress_event_users_decrement();
/* see if yield_when_idle was specified - if so, use it */
param = mca_base_param_find("mpi", NULL, "yield_when_idle");
mca_base_param_lookup_int(param, &value);
if (value < 0) {
/* if no info is provided, just default to conservative */
opal_progress_set_yield_when_idle(true);
} else {
/* info was provided, so set idle accordingly */
opal_progress_set_yield_when_idle(value == 0 ? false : true);
}
param = mca_base_param_find("mpi", NULL, "event_tick_rate");
mca_base_param_lookup_int(param, &value);
/* negative value means use default - just don't do anything */
if (value >= 0) {
opal_progress_set_event_poll_rate(value);
}
/* At this point, we are fully configured and in MPI mode. Any
communication calls here will work exactly like they would in
the user's code. Setup the connections between procs and warm
them up with simple sends, if requested */
error:
if (ret != OMPI_SUCCESS) {
const char *err_msg = opal_strerror(ret);
/* If ORTE was not setup yet, don't use orte_show_help */
if (orte_setup) {
orte_show_help("help-mpi-runtime",
"mpi_init:startup:internal-failure", true,
"MPI_INIT", "MPI_INIT", error, err_msg, ret);
} else {
opal_show_help("help-mpi-runtime",
"mpi_init:startup:internal-failure", true,
"MPI_INIT", "MPI_INIT", error, err_msg, ret);
}
return ret;
}
/* Initialize the registered datarep list to be empty */
OBJ_CONSTRUCT(&ompi_registered_datareps, opal_list_t);
/* Initialize the arrays used to store the F90 types returned by the
* MPI_Type_create_f90_XXX functions.
*/
OBJ_CONSTRUCT( &ompi_mpi_f90_integer_hashtable, opal_hash_table_t);
opal_hash_table_init(&ompi_mpi_f90_integer_hashtable, 16 /* why not? */);
OBJ_CONSTRUCT( &ompi_mpi_f90_real_hashtable, opal_hash_table_t);
opal_hash_table_init(&ompi_mpi_f90_real_hashtable, FLT_MAX_10_EXP);
OBJ_CONSTRUCT( &ompi_mpi_f90_complex_hashtable, opal_hash_table_t);
opal_hash_table_init(&ompi_mpi_f90_complex_hashtable, FLT_MAX_10_EXP);
/* All done. Wasn't that simple? */
ompi_mpi_initialized = true;
/* check for timing request - get stop time and report elapsed time if so */
if (timing && 0 == ORTE_PROC_MY_NAME->vpid) {
gettimeofday(&ompistop, NULL);
opal_output(0, "ompi_mpi_init[%ld]: time from barrier to complete mpi_init %ld usec",
(long)ORTE_PROC_MY_NAME->vpid,
(long int)((ompistop.tv_sec - ompistart.tv_sec)*1000000 +
(ompistop.tv_usec - ompistart.tv_usec)));
}
/* If desired, send a notifier message that we've finished MPI_INIT */
if (ompi_notify_init_finalize) {
orte_notifier.log(ORTE_NOTIFIER_NOTICE,
ORTE_SUCCESS,
"MPI_INIT:Finishing on host %s, pid %d",
orte_process_info.nodename,
orte_process_info.pid);
}
return MPI_SUCCESS;
}